Cloning and expression of Acinetobacter calcoaceticus catBCDE genes in Pseudomonas putida and Escherichia coli.

This report describes the isolation and preliminary characterization of a 5.0-kilobase-pair (kbp) EcoRI DNA restriction fragment carrying the catBCDE genes from Acinetobacter calcoaceticus. The respective genes encode enzymes that catalyze four consecutive reactions in the catechol branch of the beta-ketoadipate pathway: catB, muconate lactonizing enzyme (EC 5.5.1.1); catC, muconolactone isomerase (EC 5.3.3.4); catD, beta-ketoadipate enol-lactone hydrolase (EC 3.1.1.24); and catE, beta-ketoadipate succinyl-coenzyme A transferase (EC 2.8.3.6). In A. calcoaceticus, pcaDE genes encode products with the same enzyme activities as those encoded by the respective catDE genes. In Pseudomonas putida, the requirements for both catDE and pcaDE genes are met by a single set of genes, designated pcaDE. A P. putida mutant with a dysfunctional pcaE gene was used to select a recombinant pKT230 plasmid carrying the 5.0-kbp EcoRI restriction fragment containing the A. calcoaceticus catE structural gene. The recombinant plasmid, pAN1, complemented P. putida mutants with lesions in catB, catC, pcaD, and pcaE genes; the complemented activities were expressed constitutively in the recombinant P. putida strains. After introduction into Escherichia coli, the pAN1 plasmid expressed the activities constitutively but at much lower levels that those found in the P. putida transformants or in fully induced cultures of A. calcoaceticus or P. putida. When placed under the control of a lac promoter on a recombinant pUC13 plasmid in E. coli, the A. calcoaceticus restriction fragment expressed catBCDE activities at levels severalfold higher than those found in fully induced cultures of A. calcoaceticus. Thus there is no translational barrier to expression of the A. calcoaceticus genes at high levels in E. coli. The genetic origin of the cloned catBCDE genes was demonstrated by the fact that the 5.0-kbp EcoRI restriction fragment hybridized with a corresponding fragment from wild-type A. calcoaceticus DNA. This fragment was missing in DNA from an A. calcoaceticus mutant in which the cat genes had been removed by deletion. The properties of the cloned fragment demonstrate physical linkage of the catBCDE genes and suggest that they are coordinately transcribed.     

TOL plasmid can prevent induction of chemotactic responses to aromatic acids

Growth conditions that elicited positive chemotaxis to benzoate and m-toluate in TOL- Pseudomonas putida cells failed to elicit taxis to these compounds in TOL+ cells. The inability of TOL+ cells to respond to these aromatic acids appears to be due to the preferential expression of TOL-encoded genes for aromatic degradation over chromosomally encoded genes. Expression of chromosomal genes for aromatic degradation is required for cells to form beta-ketoadipate, the inducer of benzoate and m-toluate taxis.     

Similar structures in gamma-carboxymuconolactone decarboxylase and beta-ketoadipate succinyl coenzyme A transferase.

gamma-Carboxymuconolactone decarboxylase (EC 4.1.1.44) and beta-ketoadipate succinyl coenzyme A transferase (EC 2.8.3.6) mediate different steps in the beta-ketoadipate pathway. Antisera prepared against the Pseudomonas putida transferase cross-reacted immunologically with the decarboxylase from the same organism. The transferase is formed by association of two nonidentical protein subunits. The NH2-terminal amino acid sequences of the two nonidentical transferase subunits resembled each other and also were similar to the NH2-terminal amino acid sequence of the decarboxylase.     

Substrate range and genetic analysis of Acinetobacter vanillate demethylase

An Acinetobacter sp. genetic screen was used to probe structure-function relationships in vanillate demethylase, a two-component monooxygenase. Mutants with null, leaky, and heat-sensitive phenotypes were isolated. Missense mutations tended to be clustered in specific regions, most of which make known contributions to catalytic activity. The vanillate analogs m-anisate, m-toluate, and 4-hydroxy-3,5-dimethylbenzoate are substrates of the enzyme and weakly inhibit the metabolism of vanillate by wild-type Acinetobacter bacteria. PCR mutagenesis of vanAB, followed by selection for strains unable to metabolize vanillate, yielded mutant organisms in which vanillate metabolism is more strongly inhibited by the vanillate analogs. Thus, the procedure opens for investigation amino acid residues that may contribute to the binding of either vanillate or its chemical analogs to wild-type and mutant vanillate demethylases. Selection of phenotypic revertants following PCR mutagenesis gave an indication of the extent to which amino acid substitutions can be tolerated at specified positions. In some cases, only true reversion to the original amino acid was observed. In other examples, a range of amino acid substitutions was tolerated. In one instance, phenotypic reversion failed to produce a protein with the original wild-type sequence. In this example, constraints favoring certain nucleotide substitutions appear to be imposed at the DNA level.     

Deletion mutations caused by DNA strand slippage in Acinetobacter baylyi

Short nucleotide sequence repetitions in DNA can provide selective benefits and also can be a source of genetic instability arising from deletions guided by pairing between misaligned strands. These findings raise the question of how the frequency of deletion mutations is influenced by the length of sequence repetitions and by the distance between them. An experimental approach to this question was presented by the heat-sensitive phenotype conferred by pcaG1102, a 30-bp deletion in one of the structural genes for Acinetobacter baylyi protocatechuate 3,4-dioxygenase, which is required for growth with quinate. The original pcaG1102 deletion appears to have been guided by pairing between slipped DNA strands from nearby repeated sequences in wild-type pcaG. Placement of an in-phase termination codon between the repeated sequences in pcaG prevents growth with quinate and permits selection of sequence-guided deletions that excise the codon and permit quinate to be used as a growth substrate at room temperature. Natural transformation facilitated introduction of 68 different variants of the wild-type repeat structure within pcaG into the A. baylyi chromosome, and the frequency of deletion between the repetitions was determined with a novel method, precision plating. The deletion frequency increases with repeat length, decreases with the distance between repeats, and requires a minimum amount of similarity to occur at measurable rates. Deletions occurred in a recA-deficient background. Their frequency was unaffected by deficiencies in mutS and was increased by inactivation of recG.     

Dependence of linkage of alleles on their physical distance in natural transformation of Acinetobacter sp. strain ADP1

The interdependence of genetic linkage in transformation and physical distance was studied in the bacterium Acinetobacter sp. strain ADP1. Transformation experiments were performed using 17 strains containing different mutations within the 21-kb pca-qui-pob gene cluster as recipients for the DNA of one of two strains carrying a mutation causing a temperature-sensitive phenotype. The different phenotypes of the transformants (temperature-sensitive or wild-type-like) were used to evaluate linkage. Combination of the recipient and donor strains resulted in physical distances ranging from 2 bp to 10,533 bp. A logarithmic relationship of decreasing linkage and increasing distance was observed, thus leading to calibration of a system for analysis of physical distance derived from linkage data. Limitations of this application are described here: Certain mutations (3 out of 17 mutations used in this study) are an exception to the observed relationship and result in much lower linkage than expected. Observed DNA sequence repetitions leading to DNA rearrangements may be the cause of this anomaly.